/* * Copyright © 2011 Red Hat, Inc. * * Permission to use, copy, modify, distribute, and sell this software * and its documentation for any purpose is hereby granted without * fee, provided that the above copyright notice appear in all copies * and that both that copyright notice and this permission notice * appear in supporting documentation, and that the name of Red Hat * not be used in advertising or publicity pertaining to distribution * of the software without specific, written prior permission. Red * Hat makes no representations about the suitability of this software * for any purpose. It is provided "as is" without express or implied * warranty. * * THE AUTHORS DISCLAIM ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN * NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY SPECIAL, INDIRECT OR * CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS * OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, * NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * * Authors: * Peter Hutterer */ #if HAVE_CONFIG_H #include #endif #include #include #include "synapticsstr.h" #include "eventcomm.h" #define ArrayLength(a) (sizeof(a) / (sizeof((a)[0]))) int fd_read, fd_write; /* A syn event, always handy to have */ struct input_event syn = { {0, 0}, EV_SYN, SYN_REPORT, 0 }; static void create_pipe_fd(void) { int pipefd[2]; assert(pipe(pipefd) != -1); fd_read = pipefd[0]; fd_write = pipefd[1]; } static void reset_data(struct SynapticsHwState **hw, struct CommData *comm, SynapticsPrivate * priv) { SynapticsHwStateFree(&comm->hwState); memset(comm, 0, sizeof(struct CommData)); SynapticsHwStateFree(hw); *hw = SynapticsHwStateAlloc(priv); comm->hwState = SynapticsHwStateAlloc(priv); } /** * Write n input events to fd, followed by the syn event. */ static void write_event(int fd, struct input_event *ev, int n) { write(fd, ev, sizeof(struct input_event) * n); write(fd, &syn, sizeof(syn)); } static void test_buttons(int fd, InputInfoPtr pInfo, struct CommData *comm) { SynapticsPrivate *priv = (SynapticsPrivate *) pInfo->private; struct SynapticsHwState *hw = NULL; struct input_event ev = { {0, 0}, EV_KEY, 0, 0 }; reset_data(&hw, comm, priv); #define _test_press_release(_code, field) \ ev.code = (_code); \ ev.value = 1; \ write_event(fd, &ev, 1); \ EventReadHwState(pInfo, comm, hw); \ assert(hw->field == 1); \ ev.value = 0; /* button release */ \ write_event(fd_write, &ev, 1); \ EventReadHwState(pInfo, comm, hw); \ assert(hw->field == 0); _test_press_release(BTN_LEFT, left); _test_press_release(BTN_RIGHT, right); _test_press_release(BTN_MIDDLE, middle); _test_press_release(BTN_FORWARD, up); _test_press_release(BTN_BACK, down); _test_press_release(BTN_0, multi[0]); _test_press_release(BTN_1, multi[1]); _test_press_release(BTN_2, multi[2]); _test_press_release(BTN_3, multi[3]); _test_press_release(BTN_4, multi[4]); _test_press_release(BTN_5, multi[5]); _test_press_release(BTN_6, multi[6]); _test_press_release(BTN_7, multi[7]); SynapticsHwStateFree(&hw); } /** * This test checks that the recognised event fields set the right hardware * state. It's a fairly limited test and does not check whether any of the * others change the HW state at all. */ static void test_read_hw_state(void) { InputInfoRec info = { 0 }; SynapticsPrivate private; struct SynapticsHwState *hw = NULL; struct CommData comm = { 0 }; struct input_event ev[] = { {{0, 0}, EV_KEY, BTN_TOOL_FINGER, 1}, {{0, 0}, EV_KEY, BTN_TOOL_DOUBLETAP, 1}, {{0, 0}, EV_KEY, BTN_TOOL_TRIPLETAP, 1}, {{0, 0}, EV_ABS, ABS_X, 42}, {{0, 0}, EV_ABS, ABS_Y, 21}, {{0, 0}, EV_ABS, ABS_PRESSURE, 56}, {{0, 0}, EV_ABS, ABS_TOOL_WIDTH, 204}, }; memset(&private, 0, sizeof(private)); info.private = &private; info.fd = fd_read; private.proto_data = EventProtoDataAlloc(); /* just the syn event */ reset_data(&hw, &comm, &private); write(fd_write, &syn, sizeof(syn)); EventReadHwState(&info, &comm, hw); assert(hw->numFingers == 0); /* one finger */ reset_data(&hw, &comm, &private); write_event(fd_write, &ev[0], 1); EventReadHwState(&info, &comm, hw); assert(hw->numFingers == 1); /* two fingers */ reset_data(&hw, &comm, &private); write_event(fd_write, &ev[1], 1); EventReadHwState(&info, &comm, hw); assert(hw->numFingers == 2); /* three fingers */ reset_data(&hw, &comm, &private); write_event(fd_write, &ev[2], 1); EventReadHwState(&info, &comm, hw); assert(hw->numFingers == 3); /* x/y data */ reset_data(&hw, &comm, &private); write_event(fd_write, &ev[3], 2); EventReadHwState(&info, &comm, hw); assert(hw->x == ev[3].value); assert(hw->y == ev[4].value); /* pressure */ reset_data(&hw, &comm, &private); write_event(fd_write, &ev[5], 1); EventReadHwState(&info, &comm, hw); assert(hw->z == ev[5].value); /* finger width */ reset_data(&hw, &comm, &private); write_event(fd_write, &ev[6], 1); EventReadHwState(&info, &comm, hw); assert(hw->fingerWidth == ev[6].value); /* the various buttons */ test_buttons(fd_write, &info, &comm); free(private.proto_data); SynapticsHwStateFree(&hw); SynapticsHwStateFree(&comm.hwState); } static Bool compare_hw_state(const struct SynapticsHwState *a, const struct SynapticsHwState *b) { #define COMPARE(x) \ if (a->x != b->x) return a->x - b->x COMPARE(millis); COMPARE(x); COMPARE(y); COMPARE(z); COMPARE(numFingers); COMPARE(fingerWidth); COMPARE(left); COMPARE(right); COMPARE(up); COMPARE(down); if (memcmp(a->multi, b->multi, sizeof(a->multi))) return memcmp(a->multi, b->multi, sizeof(a->multi)); COMPARE(middle); #undef COMPARE return 0; } /** * Make sure that axes/keys unknown to the driver don't change the hardware * state. */ static void test_ignore_hw_state(void) { int i; InputInfoRec info = { 0 }; SynapticsPrivate private; struct SynapticsHwState *hw = NULL; struct SynapticsHwState *hw_zero = NULL; struct CommData comm = { 0 }; int known_abs[] = { ABS_X, ABS_Y, ABS_PRESSURE, ABS_TOOL_WIDTH, }; int known_keys[] = { BTN_LEFT, BTN_RIGHT, BTN_MIDDLE, BTN_FORWARD, BTN_BACK, BTN_0, BTN_1, BTN_2, BTN_3, BTN_4, BTN_5, BTN_6, BTN_7, BTN_TOOL_FINGER, BTN_TOOL_DOUBLETAP, BTN_TOOL_TRIPLETAP, BTN_TOUCH }; struct input_event ev = { {0, 0}, 0, 0, 1 }; memset(&private, 0, sizeof(private)); info.private = &private; info.fd = fd_read; private.proto_data = EventProtoDataAlloc(); reset_data(&hw_zero, &comm, &private); #define _assert_no_change(_type, _code) \ reset_data(&hw, &comm, &private); \ ev.type = _type; \ ev.code = _code; \ ev.value = 1; \ write_event(fd_write, &ev, 1); \ EventReadHwState(&info, &comm, hw); \ assert(compare_hw_state(hw, hw_zero) == 0); for (i = ABS_X; i < ABS_MAX; i++) { int j, skip = 0; for (j = 0; j < ArrayLength(known_abs); j++) { if (i == known_abs[j]) { skip = 1; break; } } if (skip) continue; _assert_no_change(EV_ABS, i); } for (i = KEY_RESERVED; i < KEY_MAX; i++) { int j, skip = 0; for (j = 0; j < ArrayLength(known_keys); j++) { if (i == known_keys[j]) { skip = 1; break; } } if (skip) continue; _assert_no_change(EV_KEY, i); } free(private.proto_data); SynapticsHwStateFree(&hw); SynapticsHwStateFree(&hw_zero); SynapticsHwStateFree(&comm.hwState); } int main(int argc, char **argv) { create_pipe_fd(); test_read_hw_state(); test_ignore_hw_state(); return 0; }